/* SPDX-FileCopyrightText: 2011-2022 Blender Foundation
 *
 * SPDX-License-Identifier: Apache-2.0 */

#pragma once

#include "kernel/globals.h"

#include "kernel/integrator/state.h"

#include "kernel/util/differential.h"

CCL_NAMESPACE_BEGIN

/* Ray */

ccl_device_forceinline void integrator_state_write_ray(IntegratorState state,
                                                       const ccl_private Ray *ccl_restrict ray)
{
#if defined(__INTEGRATOR_GPU_PACKED_STATE__) && defined(__KERNEL_GPU__)
  static_assert(sizeof(ray->P) == sizeof(float4), "Bad assumption about float3 padding");
  /* dP and dP are packed based on the assumption that float3 is padded to 16 bytes.
   * This assumption hold trues on Metal, but not CUDA.
   */
  ((ccl_private float4 &)ray->P).w = ray->dP;
  ((ccl_private float4 &)ray->D).w = ray->dD;
  INTEGRATOR_STATE_WRITE(state, ray, packed) = (ccl_private packed_ray &)*ray;

  /* Ensure that we can correctly cast between Ray and the generated packed_ray struct. */
  static_assert(offsetof(packed_ray, P) == offsetof(Ray, P),
                "Generated packed_ray struct is misaligned with Ray struct");
  static_assert(offsetof(packed_ray, D) == offsetof(Ray, D),
                "Generated packed_ray struct is misaligned with Ray struct");
  static_assert(offsetof(packed_ray, tmin) == offsetof(Ray, tmin),
                "Generated packed_ray struct is misaligned with Ray struct");
  static_assert(offsetof(packed_ray, tmax) == offsetof(Ray, tmax),
                "Generated packed_ray struct is misaligned with Ray struct");
  static_assert(offsetof(packed_ray, time) == offsetof(Ray, time),
                "Generated packed_ray struct is misaligned with Ray struct");
  static_assert(offsetof(packed_ray, dP) == 12 + offsetof(Ray, P),
                "Generated packed_ray struct is misaligned with Ray struct");
  static_assert(offsetof(packed_ray, dD) == 12 + offsetof(Ray, D),
                "Generated packed_ray struct is misaligned with Ray struct");
#else
  INTEGRATOR_STATE_WRITE(state, ray, P) = ray->P;
  INTEGRATOR_STATE_WRITE(state, ray, D) = ray->D;
  INTEGRATOR_STATE_WRITE(state, ray, tmin) = ray->tmin;
  INTEGRATOR_STATE_WRITE(state, ray, tmax) = ray->tmax;
  INTEGRATOR_STATE_WRITE(state, ray, time) = ray->time;
  INTEGRATOR_STATE_WRITE(state, ray, dP) = ray->dP;
  INTEGRATOR_STATE_WRITE(state, ray, dD) = ray->dD;
#endif
}

ccl_device_forceinline void integrator_state_read_ray(ConstIntegratorState state,
                                                      ccl_private Ray *ccl_restrict ray)
{
#if defined(__INTEGRATOR_GPU_PACKED_STATE__) && defined(__KERNEL_GPU__)
  *((ccl_private packed_ray *)ray) = INTEGRATOR_STATE(state, ray, packed);
  ray->dP = ((ccl_private float4 &)ray->P).w;
  ray->dD = ((ccl_private float4 &)ray->D).w;
#else
  ray->P = INTEGRATOR_STATE(state, ray, P);
  ray->D = INTEGRATOR_STATE(state, ray, D);
  ray->tmin = INTEGRATOR_STATE(state, ray, tmin);
  ray->tmax = INTEGRATOR_STATE(state, ray, tmax);
  ray->time = INTEGRATOR_STATE(state, ray, time);
  ray->dP = INTEGRATOR_STATE(state, ray, dP);
  ray->dD = INTEGRATOR_STATE(state, ray, dD);
#endif
}

/* Shadow Ray */

ccl_device_forceinline void integrator_state_write_shadow_ray(
    IntegratorShadowState state, const ccl_private Ray *ccl_restrict ray)
{
  INTEGRATOR_STATE_WRITE(state, shadow_ray, P) = ray->P;
  INTEGRATOR_STATE_WRITE(state, shadow_ray, D) = ray->D;
  INTEGRATOR_STATE_WRITE(state, shadow_ray, tmin) = ray->tmin;
  INTEGRATOR_STATE_WRITE(state, shadow_ray, tmax) = ray->tmax;
  INTEGRATOR_STATE_WRITE(state, shadow_ray, time) = ray->time;
  INTEGRATOR_STATE_WRITE(state, shadow_ray, dP) = ray->dP;
}

ccl_device_forceinline void integrator_state_read_shadow_ray(ConstIntegratorShadowState state,
                                                             ccl_private Ray *ccl_restrict ray)
{
  ray->P = INTEGRATOR_STATE(state, shadow_ray, P);
  ray->D = INTEGRATOR_STATE(state, shadow_ray, D);
  ray->tmin = INTEGRATOR_STATE(state, shadow_ray, tmin);
  ray->tmax = INTEGRATOR_STATE(state, shadow_ray, tmax);
  ray->time = INTEGRATOR_STATE(state, shadow_ray, time);
  ray->dP = INTEGRATOR_STATE(state, shadow_ray, dP);
  ray->dD = differential_zero_compact();
}

ccl_device_forceinline void integrator_state_write_shadow_ray_self(
    KernelGlobals kg, IntegratorShadowState state, const ccl_private Ray *ccl_restrict ray)
{
  /* There is a bit of implicit knowledge about the way how the kernels are invoked and what the
   * state is actually storing. Special logic here is needed because the intersect_shadow kernel
   * might be called multiple times. This happens when the total number of intersections by the
   * ray (shadow_path.num_hits) exceeds INTEGRATOR_SHADOW_ISECT_SIZE.
   *
   * Writing of the shadow_ray.self to the state happens only during the shadow ray setup, and
   * the shadow_isect array gets overwritten by the intersect_shadow kernel. It is important to
   * preserve the exact values of the light_object and light_prim for all invocations of the
   * intersect_shadow kernel. Hence they are written to dedicated fields in the state.
   *
   * The self.object and self.prim are kept at the latest handled intersection: during shadow path
   * branch-off it matches the main ray.self. For the consecutive calls of the intersect_shadow
   * kernels it comes from the furthest intersection (the last element of the shadow_isect). So we
   * use INTEGRATOR_SHADOW_ISECT_SIZE - 1 index for both writing and reading. This utilizes
   * knowledge that intersect_shadow kernel is only called for either initial intersection, or when
   * the number of ray intersections exceeds the shadow_isect size.
   *
   * This should help avoiding situations when the same intersection is recorded multiple times
   * throughout separate invocations of the intersect_shadow kernel. However, it is still not
   * fully reliable as there might be more than INTEGRATOR_SHADOW_ISECT_SIZE intersections at the
   * same ray->t. There is no reliable way to deal with such situation, and offsetting ray from
   * the shade_shadow kernel which will avoid potential false-positive detection of light being
   * fully blocked at the expense of potentially ignoring some intersections. If the offset is
   * used then preserving self.object and self.prim might not be as useful, but it definitely does
   * not harm. */

  INTEGRATOR_STATE_ARRAY_WRITE(
      state, shadow_isect, INTEGRATOR_SHADOW_ISECT_SIZE - 1, object) = ray->self.object;
  INTEGRATOR_STATE_ARRAY_WRITE(
      state, shadow_isect, INTEGRATOR_SHADOW_ISECT_SIZE - 1, prim) = ray->self.prim;

  INTEGRATOR_STATE_WRITE(state, shadow_ray, self_light_object) = ray->self.light_object;
  INTEGRATOR_STATE_WRITE(state, shadow_ray, self_light_prim) = ray->self.light_prim;
}

ccl_device_forceinline void integrator_state_read_shadow_ray_self(
    KernelGlobals kg, ConstIntegratorShadowState state, ccl_private Ray *ccl_restrict ray)
{
  ray->self.object = INTEGRATOR_STATE_ARRAY(
      state, shadow_isect, INTEGRATOR_SHADOW_ISECT_SIZE - 1, object);
  ray->self.prim = INTEGRATOR_STATE_ARRAY(
      state, shadow_isect, INTEGRATOR_SHADOW_ISECT_SIZE - 1, prim);
  ray->self.light_object = INTEGRATOR_STATE(state, shadow_ray, self_light_object);
  ray->self.light_prim = INTEGRATOR_STATE(state, shadow_ray, self_light_prim);
}

/* Intersection */

ccl_device_forceinline void integrator_state_write_isect(
    IntegratorState state, const ccl_private Intersection *ccl_restrict isect)
{
#if defined(__INTEGRATOR_GPU_PACKED_STATE__) && defined(__KERNEL_GPU__)
  INTEGRATOR_STATE_WRITE(state, isect, packed) = (ccl_private packed_isect &)*isect;

  /* Ensure that we can correctly cast between Intersection and the generated packed_isect struct.
   */
  static_assert(offsetof(packed_isect, t) == offsetof(Intersection, t),
                "Generated packed_isect struct is misaligned with Intersection struct");
  static_assert(offsetof(packed_isect, u) == offsetof(Intersection, u),
                "Generated packed_isect struct is misaligned with Intersection struct");
  static_assert(offsetof(packed_isect, v) == offsetof(Intersection, v),
                "Generated packed_isect struct is misaligned with Intersection struct");
  static_assert(offsetof(packed_isect, object) == offsetof(Intersection, object),
                "Generated packed_isect struct is misaligned with Intersection struct");
  static_assert(offsetof(packed_isect, prim) == offsetof(Intersection, prim),
                "Generated packed_isect struct is misaligned with Intersection struct");
  static_assert(offsetof(packed_isect, type) == offsetof(Intersection, type),
                "Generated packed_isect struct is misaligned with Intersection struct");
#else
  INTEGRATOR_STATE_WRITE(state, isect, t) = isect->t;
  INTEGRATOR_STATE_WRITE(state, isect, u) = isect->u;
  INTEGRATOR_STATE_WRITE(state, isect, v) = isect->v;
  INTEGRATOR_STATE_WRITE(state, isect, object) = isect->object;
  INTEGRATOR_STATE_WRITE(state, isect, prim) = isect->prim;
  INTEGRATOR_STATE_WRITE(state, isect, type) = isect->type;
#endif
}

ccl_device_forceinline void integrator_state_read_isect(
    ConstIntegratorState state, ccl_private Intersection *ccl_restrict isect)
{
#if defined(__INTEGRATOR_GPU_PACKED_STATE__) && defined(__KERNEL_GPU__)
  *((ccl_private packed_isect *)isect) = INTEGRATOR_STATE(state, isect, packed);
#else
  isect->prim = INTEGRATOR_STATE(state, isect, prim);
  isect->object = INTEGRATOR_STATE(state, isect, object);
  isect->type = INTEGRATOR_STATE(state, isect, type);
  isect->u = INTEGRATOR_STATE(state, isect, u);
  isect->v = INTEGRATOR_STATE(state, isect, v);
  isect->t = INTEGRATOR_STATE(state, isect, t);
#endif
}

#ifdef __VOLUME__
ccl_device_forceinline VolumeStack integrator_state_read_volume_stack(ConstIntegratorState state,
                                                                      const int i)
{
  VolumeStack entry = {INTEGRATOR_STATE_ARRAY(state, volume_stack, i, object),
                       INTEGRATOR_STATE_ARRAY(state, volume_stack, i, shader)};
  return entry;
}

ccl_device_forceinline void integrator_state_write_volume_stack(IntegratorState state,
                                                                const int i,
                                                                VolumeStack entry)
{
  INTEGRATOR_STATE_ARRAY_WRITE(state, volume_stack, i, object) = entry.object;
  INTEGRATOR_STATE_ARRAY_WRITE(state, volume_stack, i, shader) = entry.shader;
}

ccl_device_forceinline bool integrator_state_volume_stack_is_empty(KernelGlobals kg,
                                                                   ConstIntegratorState state)
{
  return (kernel_data.kernel_features & KERNEL_FEATURE_VOLUME) ?
             INTEGRATOR_STATE_ARRAY(state, volume_stack, 0, shader) == SHADER_NONE :
             true;
}

ccl_device_forceinline void integrator_state_copy_volume_stack_to_shadow(
    KernelGlobals kg, IntegratorShadowState shadow_state, ConstIntegratorState state)
{
  if (kernel_data.kernel_features & KERNEL_FEATURE_VOLUME) {
    int index = 0;
    int shader;
    do {
      shader = INTEGRATOR_STATE_ARRAY(state, volume_stack, index, shader);

      INTEGRATOR_STATE_ARRAY_WRITE(shadow_state, shadow_volume_stack, index, object) =
          INTEGRATOR_STATE_ARRAY(state, volume_stack, index, object);
      INTEGRATOR_STATE_ARRAY_WRITE(shadow_state, shadow_volume_stack, index, shader) = shader;

      ++index;
    } while (shader != OBJECT_NONE);
  }
}

ccl_device_forceinline void integrator_state_copy_volume_stack(KernelGlobals kg,
                                                               IntegratorState to_state,
                                                               ConstIntegratorState state)
{
  if (kernel_data.kernel_features & KERNEL_FEATURE_VOLUME) {
    int index = 0;
    int shader;
    do {
      shader = INTEGRATOR_STATE_ARRAY(state, volume_stack, index, shader);

      INTEGRATOR_STATE_ARRAY_WRITE(to_state, volume_stack, index, object) = INTEGRATOR_STATE_ARRAY(
          state, volume_stack, index, object);
      INTEGRATOR_STATE_ARRAY_WRITE(to_state, volume_stack, index, shader) = shader;

      ++index;
    } while (shader != OBJECT_NONE);
  }
}

ccl_device_forceinline VolumeStack
integrator_state_read_shadow_volume_stack(ConstIntegratorShadowState state, const int i)
{
  VolumeStack entry = {INTEGRATOR_STATE_ARRAY(state, shadow_volume_stack, i, object),
                       INTEGRATOR_STATE_ARRAY(state, shadow_volume_stack, i, shader)};
  return entry;
}

ccl_device_forceinline bool integrator_state_shadow_volume_stack_is_empty(
    KernelGlobals kg, ConstIntegratorShadowState state)
{
  return (kernel_data.kernel_features & KERNEL_FEATURE_VOLUME) ?
             INTEGRATOR_STATE_ARRAY(state, shadow_volume_stack, 0, shader) == SHADER_NONE :
             true;
}

ccl_device_forceinline void integrator_state_write_shadow_volume_stack(IntegratorShadowState state,
                                                                       const int i,
                                                                       VolumeStack entry)
{
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_volume_stack, i, object) = entry.object;
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_volume_stack, i, shader) = entry.shader;
}

#endif /* __VOLUME__*/

/* Shadow Intersection */

ccl_device_forceinline void integrator_state_write_shadow_isect(
    IntegratorShadowState state,
    const ccl_private Intersection *ccl_restrict isect,
    const int index)
{
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_isect, index, t) = isect->t;
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_isect, index, u) = isect->u;
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_isect, index, v) = isect->v;
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_isect, index, object) = isect->object;
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_isect, index, prim) = isect->prim;
  INTEGRATOR_STATE_ARRAY_WRITE(state, shadow_isect, index, type) = isect->type;
}

ccl_device_forceinline void integrator_state_read_shadow_isect(
    ConstIntegratorShadowState state,
    ccl_private Intersection *ccl_restrict isect,
    const int index)
{
  isect->prim = INTEGRATOR_STATE_ARRAY(state, shadow_isect, index, prim);
  isect->object = INTEGRATOR_STATE_ARRAY(state, shadow_isect, index, object);
  isect->type = INTEGRATOR_STATE_ARRAY(state, shadow_isect, index, type);
  isect->u = INTEGRATOR_STATE_ARRAY(state, shadow_isect, index, u);
  isect->v = INTEGRATOR_STATE_ARRAY(state, shadow_isect, index, v);
  isect->t = INTEGRATOR_STATE_ARRAY(state, shadow_isect, index, t);
}

#if defined(__KERNEL_GPU__)
ccl_device_inline void integrator_state_copy_only(KernelGlobals kg,
                                                  ConstIntegratorState to_state,
                                                  ConstIntegratorState state)
{
  int index;

  /* Rely on the compiler to optimize out unused assignments and `while(false)`'s. */

#  define KERNEL_STRUCT_BEGIN(name) \
    index = 0; \
    do {

#  define KERNEL_STRUCT_MEMBER(parent_struct, type, name, feature) \
    if (kernel_integrator_state.parent_struct.name != nullptr) { \
      kernel_integrator_state.parent_struct.name[to_state] = \
          kernel_integrator_state.parent_struct.name[state]; \
    }

#  ifdef __INTEGRATOR_GPU_PACKED_STATE__
#    define KERNEL_STRUCT_BEGIN_PACKED(parent_struct, feature) \
      KERNEL_STRUCT_BEGIN(parent_struct) \
      KERNEL_STRUCT_MEMBER(parent_struct, packed_##parent_struct, packed, feature)
#    define KERNEL_STRUCT_MEMBER_PACKED(parent_struct, type, name, feature)
#  else
#    define KERNEL_STRUCT_MEMBER_PACKED KERNEL_STRUCT_MEMBER
#    define KERNEL_STRUCT_BEGIN_PACKED(parent_struct, feature) KERNEL_STRUCT_BEGIN(parent_struct)
#  endif

#  define KERNEL_STRUCT_ARRAY_MEMBER(parent_struct, type, name, feature) \
    if (kernel_integrator_state.parent_struct[index].name != nullptr) { \
      kernel_integrator_state.parent_struct[index].name[to_state] = \
          kernel_integrator_state.parent_struct[index].name[state]; \
    }

#  define KERNEL_STRUCT_END(name) \
    } \
    while (false) \
      ;

#  define KERNEL_STRUCT_END_ARRAY(name, cpu_array_size, gpu_array_size) \
    ++index; \
    } \
    while (index < gpu_array_size) \
      ;

#  define KERNEL_STRUCT_VOLUME_STACK_SIZE kernel_data.volume_stack_size

#  include "kernel/integrator/state_template.h"

#  undef KERNEL_STRUCT_BEGIN
#  undef KERNEL_STRUCT_BEGIN_PACKED
#  undef KERNEL_STRUCT_MEMBER
#  undef KERNEL_STRUCT_MEMBER_PACKED
#  undef KERNEL_STRUCT_ARRAY_MEMBER
#  undef KERNEL_STRUCT_END
#  undef KERNEL_STRUCT_END_ARRAY
#  undef KERNEL_STRUCT_VOLUME_STACK_SIZE
}

ccl_device_inline void integrator_state_move(KernelGlobals kg,
                                             ConstIntegratorState to_state,
                                             ConstIntegratorState state)
{
  integrator_state_copy_only(kg, to_state, state);

  INTEGRATOR_STATE_WRITE(state, path, queued_kernel) = 0;
}

ccl_device_inline void integrator_shadow_state_copy_only(KernelGlobals kg,
                                                         ConstIntegratorShadowState to_state,
                                                         ConstIntegratorShadowState state)
{
  int index;

  /* Rely on the compiler to optimize out unused assignments and `while(false)`'s. */

#  define KERNEL_STRUCT_BEGIN(name) \
    index = 0; \
    do {

#  define KERNEL_STRUCT_MEMBER(parent_struct, type, name, feature) \
    if (kernel_integrator_state.parent_struct.name != nullptr) { \
      kernel_integrator_state.parent_struct.name[to_state] = \
          kernel_integrator_state.parent_struct.name[state]; \
    }

#  ifdef __INTEGRATOR_GPU_PACKED_STATE__
#    define KERNEL_STRUCT_BEGIN_PACKED(parent_struct, feature) \
      KERNEL_STRUCT_BEGIN(parent_struct) \
      KERNEL_STRUCT_MEMBER(parent_struct, type, packed, feature)
#    define KERNEL_STRUCT_MEMBER_PACKED(parent_struct, type, name, feature)
#  else
#    define KERNEL_STRUCT_MEMBER_PACKED KERNEL_STRUCT_MEMBER
#    define KERNEL_STRUCT_BEGIN_PACKED(parent_struct, feature) KERNEL_STRUCT_BEGIN(parent_struct)
#  endif

#  define KERNEL_STRUCT_ARRAY_MEMBER(parent_struct, type, name, feature) \
    if (kernel_integrator_state.parent_struct[index].name != nullptr) { \
      kernel_integrator_state.parent_struct[index].name[to_state] = \
          kernel_integrator_state.parent_struct[index].name[state]; \
    }

#  define KERNEL_STRUCT_END(name) \
    } \
    while (false) \
      ;

#  define KERNEL_STRUCT_END_ARRAY(name, cpu_array_size, gpu_array_size) \
    ++index; \
    } \
    while (index < gpu_array_size) \
      ;

#  define KERNEL_STRUCT_VOLUME_STACK_SIZE kernel_data.volume_stack_size

#  include "kernel/integrator/shadow_state_template.h"

#  undef KERNEL_STRUCT_BEGIN
#  undef KERNEL_STRUCT_BEGIN_PACKED
#  undef KERNEL_STRUCT_MEMBER
#  undef KERNEL_STRUCT_MEMBER_PACKED
#  undef KERNEL_STRUCT_ARRAY_MEMBER
#  undef KERNEL_STRUCT_END
#  undef KERNEL_STRUCT_END_ARRAY
#  undef KERNEL_STRUCT_VOLUME_STACK_SIZE
}

ccl_device_inline void integrator_shadow_state_move(KernelGlobals kg,
                                                    ConstIntegratorState to_state,
                                                    ConstIntegratorState state)
{
  integrator_shadow_state_copy_only(kg, to_state, state);

  INTEGRATOR_STATE_WRITE(state, shadow_path, queued_kernel) = 0;
}

#endif

/* NOTE: Leaves kernel scheduling information untouched. Use INIT semantic for one of the paths
 * after this function. */
ccl_device_inline IntegratorState integrator_state_shadow_catcher_split(KernelGlobals kg,
                                                                        IntegratorState state)
{
#if defined(__KERNEL_GPU__)
  ConstIntegratorState to_state = atomic_fetch_and_add_uint32(
      &kernel_integrator_state.next_main_path_index[0], 1);

  integrator_state_copy_only(kg, to_state, state);
#else
  IntegratorStateCPU *ccl_restrict to_state = state + 1;

  /* Only copy the required subset for performance. */
  to_state->path = state->path;
  to_state->ray = state->ray;
  to_state->isect = state->isect;
#  ifdef __VOLUME__
  integrator_state_copy_volume_stack(kg, to_state, state);
#  endif
#endif

  return to_state;
}

#ifndef __KERNEL_GPU__
ccl_device_inline int integrator_state_bounce(ConstIntegratorState state, const int /*unused*/)
{
  return INTEGRATOR_STATE(state, path, bounce);
}

ccl_device_inline int integrator_state_bounce(ConstIntegratorShadowState state,
                                              const int /*unused*/)
{
  return INTEGRATOR_STATE(state, shadow_path, bounce);
}

ccl_device_inline int integrator_state_diffuse_bounce(ConstIntegratorState state,
                                                      const int /*unused*/)
{
  return INTEGRATOR_STATE(state, path, diffuse_bounce);
}

ccl_device_inline int integrator_state_diffuse_bounce(ConstIntegratorShadowState state,
                                                      const int /*unused*/)
{
  return INTEGRATOR_STATE(state, shadow_path, diffuse_bounce);
}

ccl_device_inline int integrator_state_glossy_bounce(ConstIntegratorState state,
                                                     const int /*unused*/)
{
  return INTEGRATOR_STATE(state, path, glossy_bounce);
}

ccl_device_inline int integrator_state_glossy_bounce(ConstIntegratorShadowState state,
                                                     const int /*unused*/)
{
  return INTEGRATOR_STATE(state, shadow_path, glossy_bounce);
}

ccl_device_inline int integrator_state_transmission_bounce(ConstIntegratorState state,
                                                           const int /*unused*/)
{
  return INTEGRATOR_STATE(state, path, transmission_bounce);
}

ccl_device_inline int integrator_state_transmission_bounce(ConstIntegratorShadowState state,
                                                           const int /*unused*/)
{
  return INTEGRATOR_STATE(state, shadow_path, transmission_bounce);
}

ccl_device_inline int integrator_state_transparent_bounce(ConstIntegratorState state,
                                                          const int /*unused*/)
{
  return INTEGRATOR_STATE(state, path, transparent_bounce);
}

ccl_device_inline int integrator_state_transparent_bounce(ConstIntegratorShadowState state,
                                                          const int /*unused*/)
{
  return INTEGRATOR_STATE(state, shadow_path, transparent_bounce);
}
#else
ccl_device_inline int integrator_state_bounce(ConstIntegratorShadowState state,
                                              const uint32_t path_flag)
{
  return (path_flag & PATH_RAY_SHADOW) ? INTEGRATOR_STATE(state, shadow_path, bounce) :
                                         INTEGRATOR_STATE(state, path, bounce);
}

ccl_device_inline int integrator_state_diffuse_bounce(ConstIntegratorShadowState state,
                                                      const uint32_t path_flag)
{
  return (path_flag & PATH_RAY_SHADOW) ? INTEGRATOR_STATE(state, shadow_path, diffuse_bounce) :
                                         INTEGRATOR_STATE(state, path, diffuse_bounce);
}

ccl_device_inline int integrator_state_glossy_bounce(ConstIntegratorShadowState state,
                                                     const uint32_t path_flag)
{
  return (path_flag & PATH_RAY_SHADOW) ? INTEGRATOR_STATE(state, shadow_path, glossy_bounce) :
                                         INTEGRATOR_STATE(state, path, glossy_bounce);
}

ccl_device_inline int integrator_state_transmission_bounce(ConstIntegratorShadowState state,
                                                           const uint32_t path_flag)
{
  return (path_flag & PATH_RAY_SHADOW) ?
             INTEGRATOR_STATE(state, shadow_path, transmission_bounce) :
             INTEGRATOR_STATE(state, path, transmission_bounce);
}

ccl_device_inline int integrator_state_transparent_bounce(ConstIntegratorShadowState state,
                                                          const uint32_t path_flag)
{
  return (path_flag & PATH_RAY_SHADOW) ? INTEGRATOR_STATE(state, shadow_path, transparent_bounce) :
                                         INTEGRATOR_STATE(state, path, transparent_bounce);
}
#endif

CCL_NAMESPACE_END
